An apparatus of structured light generation is equipped with a light source and a lens unit. The lens unit is installed in a compact housing of the apparatus of structured light generation. Moreover, the lens unit constructed two different optical path lengths within the housing. By the lens unit, light beams from the light source are collimated and converted into linear light beams. The linear light beams are locally overlapped or globally overlapped. Consequently, the light beam from the light source is shaped into a linear structured light or a linearly-overlapped structured light for detection.
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2. The apparatus of structured light generation according to
3. The apparatus of structured light generation according to
4. The apparatus of structured light generation according to
5. The apparatus of structured light generation according to
where, r2=x2+y2,
wherein ϕ(r) is the phase distribution, r is the distance between any point and a center of the first surface, and x and y are two coordinates of two axes vertical to an optical axis or a Z axis, wherein dor=1, df0=0.0, df1=−6.1691×10^(−1), df1=2.8442×10^1, df3=−4.8405×10^3, df4=2.800×10^5, df5=4.6892×10^(−2), and df6=3.1385×10^(−4).
6. The apparatus of structured light generation according to
7. The apparatus of structured light generation according to
8. The apparatus of structured light generation according to
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This application is a Divisional of co-pending continuation-in-part application Ser. No. 15/071,935, filed on Mar. 16, 2016, which claims priority of U.S. application Ser. No. 14/595,651, filed January 13, 2015, now U.S. Pat. No. 9,322,962, for which priority is claimed under 35 U.S.C. § 120; and this application claims priority of Application Nos. 1036137857, 103219360, 103137850 filed in Taiwan on Oct. 31, 2014 under 35 U.S.C. § 119; the entire contents of all of which are hereby incorporated by reference.
The present invention relates to an apparatus of structured light generation, and more particularly to a slim-type apparatus of structured light generation.
In recent years, the elements, devices, modules, apparatuses or instruments for detecting interactive gestures, postures or 3D scanning trajectories have been increasingly developed. For example, an infrared (IR) structured light can be employed to achieve the above detecting function. In the meantime, a planar scanning structured light is also preferred to employ in recognizing the interactive actions or the important indicating objects. In practical implementation, a collimating beam is required in the generation mechanism to make such a structured light. As a result, a collimated infrared light is necessary to achieve this function. However, since the current light source module with the function of generating the collimated light has bulky volume, this light source module cannot meet the requirements of the modern slim type mobile phone, wearable devices, and so on.
On the other hand, the current light source module is usually equipped with a dust-proof lens at a side of a housing thereof. The dust-proof lens can increase the resistance of the light source to the harsh environment and enhance the stability of the light source. The material of the dust-proof lens is typically a glass plate. In some situations, the dust-proof lens may be omitted or integrated into other part. However, if the dust-proof lens is omitted, the optical path length or the working distance is possibly changed. The change of the optical path length or the working distance may adversely affect the operation of the light source module, i.e., the effective back focal length is changed and the collimating property is varied. Therefore, it is important to develop a lens which is capable to work well both with/or without the dust-proof lens and install it in a compact-size and user-friendly apparatus of structured light generation in a mobile phone so as to extract 3D information or achieve the 3D gesture or scanning function.
An object of the present invention provides an apparatus of structured light generation for achieving a 3D sensing function. The apparatus of structured light generation uses a lens unit to construct at least two optical path lengths. Consequently, the flexibility of using the apparatus of structured light generation is enhanced.
Another object of the present invention provides an apparatus of structured light generation comprising a lens unit with a lens element. The lens element has a first surface for collimating a visible or invisible laser beam and a second surface for shaping the collimated laser beam as a linear light beam. Consequently, the parallel linear light beam is generated.
In accordance with an aspect of the present invention, an apparatus of structured light generation is provided. The apparatus of structured light generation includes a light source, a lens unit and a housing. The light source emits a light beam. The lens unit converts the light beam into a linear light beam. The lens unit includes a lens element with a first surface and a second surface. The first surface and the second surface are opposed to each other. The first surface faces the light source. In addition, the first surface has a radius larger than 0.189 mm or has a diffracting function. The housing accommodates the light source and the lens unit. Within the housing, the lens unit constructs a first optical path length and a second optical path length for the light beam. The first optical path length and the second optical path length are different.
In an embodiment, the first surface of the lens element is an aspheric surface or a free-form surface, and a lenticular lens array structure is formed on the second surface of the lens element. Alternatively, a lenticular lens array structure is formed on the first surface of the lens element, and the second surface of the lens element is an aspheric surface or a free-form surface.
In an embodiment, the lens unit further includes a dust-proof plate between the light source and the lens element, and the lens element and the dust-proof plate are made of an identical material or different materials. In this circumstance, the materials can be glass or non-glass type.
In an embodiment, the lens unit further includes a mixed type optical structure. The mixed type optical structure contains a diffractive structure, a reflective structure and/or a refractive structure. The mixed type optical structure is arranged between the light source and the lens element.
In an embodiment, the first surface of the lens element has a phase distribution given by a formula:
In an embodiment, the light beam is collimated by the first surface of the lens element, and the collimated light beam is converted into the linear light beam by the second surface of the lens element.
In an embodiment, the lens unit further includes a dust-proof plate between the light source and the lens element. The lens element and the dust-proof plate are made of an identical material or different materials. The lens element is made of poly(methyl methacrylate), polycarbonate, cyclo-olefin polymer or high density polyethylene, which is transparent in a corresponding wavelength range.
In an embodiment, the first surface of the lens element has an aspheric surface, a lenticular lens array structure is formed on the second surface of the lens element, and a surface profile of the aspheric surface is given by a following formula:
wherein z is a Z-axis coordinate of a specified point on the aspheric surface from a vertex, CV is a radius of curvature, CC is a conic coefficient, as0=as1=0.0, as2=9.6037×10^1, as3=−4.1955×10^3, as4=−2.5357×10^4, as5=−7.2472×10^1, and as6=−3.0699.
In an embodiment, the first surface of the lens element is a flat surface with the diffracting function, and the first surface has a phase distribution given by a formula:
In an embodiment, a lenticular lens array structure is formed on the first surface of the lens element, the second surface of the lens element has an aspheric surface, and a surface profile of the aspheric surface is given by a following formula:
wherein z is a Z-axis coordinate of a specified point on the aspheric surface from a vertex, CV is a radius of curvature, CC is a conic coefficient, as0=as1=0.0, as2=9.6037×10^1, as3=−4.1955×10^3, as4=−2.5357×10^4, as5=−7.2472×10^1, and as6=−3.0699.
In an embodiment, the first optical path length or the second optical path length comprises one or plural working distances. Moreover, a difference between the plural working distances is smaller than 1.2 mm.
In an embodiment, the light source includes plural light-emitting chips, and the lens element includes plural light-transmissible regions. After the light beam from each of the light-emitting chips passes through the corresponding light-transmissible region of the lens element, the light beam is converted into at least one linear light beam by the corresponding light-transmissible region. The linear light beams outputted from the plural light-transmissible regions are locally overlapped, globally overlapped, or not overlapped.
In accordance with another aspect of the present invention, an apparatus of structured light generation is provided. The apparatus of structured light generation includes a light source, a lens unit and a housing. The light source emits a light beam. The lens unit converts the light beam into a linear light beam. The housing accommodates the light source and the lens unit. The housing includes a first side and a second side. The first side and the second side are opposed to each other and open to an outside of the casing. A distance between the first side and the second side is not larger than 4 mm. The light source is located near the first side. The lens unit is located near the second side. Within the housing, the lens unit constructs a first optical path length and a second optical path length for the light beam. Moreover, the first optical path length and the second optical path length are different.
In an embodiment, the lens unit includes a lens element, and a radius of a first surface of the lens element is larger than 0.189 mm. The first surface faces the light source. The first surface is an aspheric surface or has a lenticular lens array structure. The first surface has an effective focal length smaller than 1.2 mm.
In an embodiment, a second surface of the lens element is an aspheric surface or has a lenticular lens array structure, and the second surface of the lens unit is close to the second side of the housing and faces the outside of the housing.
In an embodiment, the lens unit further includes a dust-proof plate between the light source and the lens element.
In an embodiment, the lens unit includes a lens element. A first surface of the lens element is a flat surface with a diffracting function. The first surface has a phase distribution given by a formula:
In an embodiment, the light source includes plural light-emitting chips, and the lens element includes plural light-transmissible regions. After the light beam from each of the light-emitting chips passes through the corresponding light-transmissible region of the lens element, the light beam is converted into at least one linear light beam by the corresponding light-transmissible region. The linear light beams outputted from the plural light-transmissible regions are locally overlapped, globally overlapped, or not overlapped.
In an embodiment, the plural light-emitting chips are programmed to be individually turned on or turned off in identical or different time segments.
In an embodiment, the light source includes one light-emitting chip, or the light source includes plural light-emitting chips that are distributed on a curvy substrate.
The above objects and advantages of the present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
The light source 10 includes one or plural light-emitting chips 102 and a package structure 101. For example, the light-emitting chip 102 may emit an infrared laser beam with a wavelength of 830 nm and a diffusion angle of about 20 degrees. In addition, the light-emitting chip 102 is packaged by the package structure 101. The number of the one or plural light-emitting chips 102 packaged within the package structure 101 is not restricted. In an embodiment, plural light-emitting chips 102 are firstly distributed on different positions of a substrate and then covered by the package structure 101. For clarification and brevity, only a single light-emitting chip 102 is shown in
In this embodiment, the lens unit 14 includes a lens element, wherein a numerical aperture of the lens element is larger than 0.1 and less than 0.5, preferably about 0.2. The lens element includes a first surface 141 and a second surface 143. The first surface 141 is a curvy surface with a curvature of radius larger than 0.189 mm. The second surface 143 has another optical structure. The first surface 141 faces the light source 10 (or the first side 121 of the housing 12), and the second surface 143 faces the second side 123 of the housing 12. The distance between the first surface 141 of the lens element and the light source 10 is about 1.00 mm. The light source 10 may emit a light beam. The lens unit 14 constructs a first optical path length for the light beam. Moreover, the first surface 141 of the lens element is an aspheric surface or a free-form surface for collimating the light beam from the light source 10. Preferably, the radius of the first surface 141 is in the range between 0.18935 and 0.1894 mm. The surface profile of the aspheric surface may be expressed by the Z-axis coordinate of a specified point on the aspheric surface. The Z axis is in parallel with the optical axis. In particular, the surface profile of the aspheric surface may be given by the following formula:
In the above formula, z is the Z-axis coordinate of a specified point on the aspheric surface from the vertex, CV is the radius of curvature, CC is the conic coefficient, (asn) indicate the aspheric coefficients corresponding to different order terms of radius, wherein n indicates 0 or a positive integer. For example, as0=as1=0.0, as2=9.6037 ×10^1, as3=−4.1955×10^3, as4=−2.5357×10^4, as5=−7.2472×10^1, and as6=−3.0699. It is noted that the aspheric coefficients are not limited thereto. Moreover, the effective focal length of the lens element is preferably smaller than 1.2 mm, and more preferably smaller than 1.0 mm. The lens element is made of poly(methyl methacrylate) (PMMA) or any other appropriate transparent material in a corresponding wavelength range. For example, the transparent material is polycarbonate (PC), cyclo-olefin polymer (COP resin) or high density polyethylene (HDPE).
In this embodiment, after the collimated light beam is converted into a linear light beam by the second surface 143 of the lens element, a structured light is outputted from the apparatus of structured light generation 1. It is noted that numerous modifications and alterations may be made while retaining the teachings of the invention.
In the above formula, ϕ(r) is the phase distribution, r is the distance between any point and a center of the first surface 341, and x and y are two coordinates of two axes vertical to the optical axis (i.e. the Z axis). Preferably, the corresponding coefficients include: dor=1, df0 =0.0, df1=−6.1691×10^(−1), df1=2.8442×10^1, df3=−4.8405×10^3, df4=2.800×10^5, df5=4.6892×10^(−2), and df6=3.1385×10^(−4).
It is noted that numerous modifications and alterations may be made while retaining the teachings of the invention. For example, the profiles of the first surface and the second surface of the lens element may be exchanged.
Please refer to
It is noted that the mixed type optical structure is not restricted to the second lens element 542 of the lens unit 54. For example, in some other embodiments, the mixed type optical structure contains a diffractive structure, a reflective structure and/or a refractive structure.
In this embodiment, lenticular lens array structures are formed on the inner surfaces of the corresponding light-transmissible regions 542a, 542b, 542c and 542d, and a lenticular lens array structure along two orthogonal directions is formed on the inner surface of the light-transmissible region 542e. The profiles of the inner surfaces of the above light-transmissible regions are presented herein for purpose of illustration and description only. It is noted that the lenticular lens array structures on the inner surfaces of the light-transmissible regions may be arranged along different directions or have different tilt angles.
In this embodiment, the housing 52 has a shape of a rectangular sleeve, and the circuit substrate 502 and the first lens element 541 have the shapes of rectangular plates. It is noted that numerous modifications and alterations may be made while retaining the teachings of the invention. In the variant example of
Please refer to
From the above descriptions, the present invention provides the apparatus of structured light generation. In the apparatus of structured light generation, the lens element with the functions of simultaneously collimating and shaping the light beam is used as the basic element of the lens unit. Consequently, the apparatus of structured light generation can be applied to an optical system with at least two optical path lengths in order to generate the infrared structured light. The optical path length is composed of one or plural working distances. The plural working distances may be identical or different as long as the difference between the working distances is smaller than 1.0 mm. In other words, the optical system with the apparatus of structured light generation of the present invention is more flexible to be conveniently operated by the user. Since the apparatus of structured light generation of the present invention has a compact size, the apparatus of structured light generation is suitably installed in the slim type mobile phone. Consequently, regardless of whether the apparatus of structured light generation is installed on a front side or a rear side of the mobile phone, the mobile phone has the function of generating the structured light.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiments. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
Chern, Jyh-Long, Yen, Chih-Ming
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